Wettability in complex porous materials, the mixed-wet state, and its relationship to surface roughness

Wettability in complex porous materials, the mixed-wet state, and its relationship to surface roughness

A quantitative in situ characterization of the impact of surface roughness on wettability in porous media is currently lacking. We use reservoir condition micrometer-resolution X-ray tomography combined with automated methods for the measurement of contact angle, interfacial curvature, and surface r...

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Bibliographic Details
Published in:Proceedings of the National Academy of Sciences - PNAS Vol. 115; no. 36; pp. 8901 - 8906
Main Authors: AlRatrout, Ahmed, Blunt, Martin J., Bijeljic, Branko
Format: Journal Article
Language:English
Published: United States National Academy of Sciences 04-09-2018
Subjects:
Aquifers
Automation
Carbon dioxide
Carbon sequestration
Contact angle
Curvature
Fluid flow
Gases
Hydrophobicity
Interfaces
Limestone
Measurement methods
Oil and gas fields
Oil field equipment
Physical Sciences
Porous materials
Porous media
Solid surfaces
Surface roughness
Tomography
Wettability
Wetting
X-rays
in situ reservoir conditions
contact angle
roughness
complex porous media
curvature
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Summary:A quantitative in situ characterization of the impact of surface roughness on wettability in porous media is currently lacking. We use reservoir condition micrometer-resolution X-ray tomography combined with automated methods for the measurement of contact angle, interfacial curvature, and surface roughness to examine fluid/fluid and fluid/solid interfaces inside a porous material. We study oil and water in the pore space of limestone from a giant producing oilfield, acquiring millions of measurements of curvature and contact angle on three millimeter-sized samples. We identify a distinct wetting state with a broad distribution of contact angle at the submillimeter scale with a mix of water-wet and water-repellent regions. Importantly, this state allows both fluid phases to flow simultaneously over a wide range of saturation. We establish that, in media that are largely water wet, the interfacial curvature does not depend on solid surface roughness, quantified as the local deviation from a plane. However, where there has been a significant wettability alteration, rougher surfaces are associated with lower contact angles and higher interfacial curvature. The variation of both contact angle and interfacial curvature increases with the local degree of roughness. We hypothesize that this mixed wettability may also be seen in biological systems to facilitate the simultaneous flow of water and gases; furthermore, wettability-altering agents could be used in both geological systems and material science to design a mixed-wetting state with optimal process performance.
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Author contributions: A.A., M.J.B., and B.B. designed research; A.A. performed research; A.A., M.J.B., and B.B. contributed new analytic tools; A.A., M.J.B., and B.B. analyzed data; and A.A., M.J.B., and B.B. wrote the paper.
Edited by David A. Weitz, Harvard University, Cambridge, MA, and approved July 17, 2018 (received for review March 3, 2018)
ISSN:0027-8424
1091-6490
DOI:10.1073/pnas.1803734115